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          <h1 class="margin-bottom-hight">Applications</h1>
          <span>Discover the diverse research areas empowered by Thunders Biotech's functional ultrasound technology.</span>
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          <h1 class="margin-bottom m-auto">Versatile Neuroimaging Across Disciplines</h1>
          <span>
            The mini-fUS system's high spatiotemporal resolution, deep penetration, and suitability for freely moving subjects make it a powerful tool for a
            wide range of neuroscience applications. It enables researchers to explore brain function and dysfunction with unprecedented detail and in more
            naturalistic experimental settings.
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          <h1 class="margin-bottom m-auto">Resting-State Functional Connectivity (rsFC)</h1>
          <p>
            mini-fUS allows for robust mapping of brain-wide rsFC networks in awake, freely moving animals. Its sensitivity to subtle hemodynamic fluctuations
            provides valuable insights into intrinsic brain organization and alterations in disease models. This capability is crucial for understanding
            baseline neural communication and how it is affected by various factors.
          </p>
          <p class="block"><span class="link">Learn More</span></p>
        </article>
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    <section class="sec-box h-screen flex-column-sc text-center applications-home">
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          <h1 class="margin-bottom m-auto">Functional Neuroimaging (Task-Evoked)</h1>
          <p>
            Investigate neural responses to sensory stimuli, motor tasks, or cognitive challenges. The mini-fUS system can detect transient, localized brain
            activity on single trials, as demonstrated in studies like whisker stimulation in mice, providing clear visualization of activation patterns and
            their temporal dynamics.
          </p>
          <p class="block"><span class="link">Learn More</span></p>
        </article>
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    <section class="sec-box h-screen flex-column-sc text-center applications-home">
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          <h1 class="margin-bottom m-auto">Vascular Imaging</h1>
          <p>
            Leverage the high sensitivity of mini-fUS for detailed visualization of cerebral vasculature and quantification of cerebral blood volume (CBV) and
            flow. The system can resolve microvessels deep within the brain, offering critical information for studies on neurovascular coupling, stroke, and
            other cerebrovascular conditions. Examples include imaging mouse embryo brains and validating flow in phantoms.
          </p>
          <p class="block"><span class="link">Learn More</span></p>
        </article>
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          <h1 class="margin-bottom m-auto">Neuropharmacology</h1>
          <p>
            Track the effects of pharmacological agents on brain activity and hemodynamics in real-time. mini-fUS can quantify drug-induced changes in CBV and
            assess hemodynamic variability, as shown in studies investigating the effects of anesthetics like isoflurane. This provides a powerful tool for drug
            discovery and understanding mechanisms of drug action in the brain.
          </p>
          <p class="block"><span class="link">Learn More</span></p>
        </article>
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